Description RotaMass 3 Series Coriolis Mass Flow Meter; - Integral Transmitter, Model RCCx; - Remote Converter, Model RCCF31; - Remote Converter, Model RCCR31; - Remote Detector Model RCCS3xxxx The Coriolis Mass Flow Meter is used for direct measurement of a gas or liquid mass flow using the Coriolis principle. The integral version combines the detector and the converter in one apparatus; the separate version consists of a converter and a separate detector, connected via a cable. The Detector may be provided with a heat conductor, consisting of heating pipes supplied by a heat conducting medium (e.g. water, oil or gas). Model codes and Options Integral Transmitter Model RCCa b, where a = meter size (4, 6, 8, 9, 9(/)IR, 9J, 9(/)XR, 9X) b = /FB - Foundation Fieldbus communication /EF1 - non-intrinsically safe output signals /EF2 - intrinsically safe output signals /EF3 - non-intrinsically safe output signals, with /FB (Foundation Fieldbus) /EF4 - intrinsically safe output signals with /FB (Foundation Fieldbus) /HP - high driving power Remote Converter Model RCCF31 a, where a = /FB - Foundation Fieldbus communication /EF1 - non-intrinsically safe output signals /EF2 - intrinsically safe output signals /EF3 - non-intrinsically safe output signals, with /FB (Foundation Fieldbus) /EF4 - intrinsically safe output signals with /FB (Foundation Fieldbus) /HP - high driving power Remote Converter Model RCCR31 a, where a = /FB - Foundation Fieldbus communication /ES1 - non-intrinsically safe output signals /ES3 - non-intrinsically safe output signals, with /FB (Foundation Fieldbus) /HP - high driving power Page 1 of 6
Remote Detector Model RCCS3a b, where a = meter size (0, 0/LR, 1, 2, 3, 4, 6, 8, 9, 9(/)IR, 9J, 9(/)XR, 9X) b = /ES1 - Standard version /MT - process temperature up to 220 C /HT - process temperature up to 350 C /T1 - Factory insulation / - Factory insulation and heat carrier heating / - Factory insulation and heat carrier heating and ventilation /S2 - Terminal box on extension part Equipment marking Model code (incl. options) Marking RCC. /EF1 or /EF3 Ex d [ib] IIC... or Ex de [ib] IIC... *) and RCC. /EF2 or /EF4 Ex d [ia][ib] IIC... or Ex de [ia][ib] IIC... *) and RCC. /EF1 or /EF3, /HP Ex d [ib] IIB... or Ex de [ib] IIB... *) and RCC. /EF2 or /EF4, /HP Ex d [ia][ib] IIB... or Ex de [ia][ib] IIB... *) and RCCF31 /EF1 or /EF3 Ex d [ib] IIC or Ex de [ib] IIC and RCCF31 /EF2 or /EF4 Ex d [ia][ib] IIC or Ex de [ia][ib] IIC and RCCF31 /EF1 or /EF3, /HP Ex d [ib] IIB or Ex de [ib] IIB and RCCF31 /EF2 or /EF4, /HP Ex d [ia][ib] IIB or Ex de [ia][ib] IIB and RCCR31 /ES1 or /ES3 [Ex ib] IIC and [Ex ibd] RCCR31 /ES1 or /ES3, /HP [Ex ib] IIB and [Ex ibd] RCCS3.... Ex ib IIB/IIC T1... *) and Ex ibd 21 Txx *) *) Refer to thermal data below for temperature class assignment and appropriate maximum surface temperature T Page 2 of 6
Ambient temperature and process temperature The relation between ambient temperature, process temperature, temperature class and maximum surface temperature T is listed in the following overview: Integral Transmitter Model RCC...: Temperature Ambient temperature class -40 C... +55 C Remote Converter Model RCCF31...: Ambient temperature range -40 C... +55 C Temperature class Maximum surface temperature T 75 C Remote Converter Model RCCR31...: Ambient temperature range -40 C... +55 C Process Temperature -50 C... +115 C Max. surface temperature T 150 C Remote Detector Model RCCS30 to RCCS33 and RCCS30/LR (without insulation): -50 C... +50 C -50 C... +50 C -50 C... +50 C Maximum surface temperature T 150 C. -50 C... +60 C -50 C... +100 C -50 C... +120 C Remote Detector Model RCCS30 to RCCS33 and RCCS30/LR (with insulation): -50 C... +60 C Maximum surface temperature T 150 C. -50 C... +60 C -50 C... +90 C -50 C... +130 C Page 3 of 6
Remote Detector Model RCCS34 to RCCS39, RCCS39(/)IR, RCCS39(/)XR, RCCS39J, RCCS39X without insulation: -50 C... +55 C -50 C... +55 C -50 C... +100 C -50 C... +120 C -50 C... +160 C -50 C... +180 C -50 C... +220 C Maximum surface temperature T 150 C (standard version), respectively T 220 C (option /MT). Page 4 of 6
Remote Detector Model RCCS34 to RCCS39, RCCS39(/)IR, RCCS39(/)XR, RCCS39J, RCCS39X with factory insulation (options /T1, / and /): T1-50 C... +75 C -50 C... +70 C -50 C... +70 C -50 C... +45 C -50 C... +75 C -50 C... +115 C -50 C... +180 C -50 C... +275 C -50 C... +350 C Maximum surface temperature T 150 C (standard version), respectively T 220 C (option /MT), respectively 350 C (option /HT). Electrical data Integral Transmitter Model RCC... and Remote Converters Models RCCF31 and RCCR31: Supply: 90... 250 Vac, 50/60 Hz or 20,5... 28,8 Vdc Power consumption: Max. 10 W Output signals: Option /EF1 and /ES1: 4-20 ma current output and pulse output Option /EF3 and /ES3: Foundation Fieldbus Option /EF2: Current output (terminals Iout1+ and Iout1-) in type of protection intrinsic safety Ex ia IIC, for connection to a certified intrinsically safe circuit, with following entity parameters: Ui = 30 V, Ii = 165 ma, Pi = 1,25 W, Ci = 6,9 nf, Li = 0 mh; Pulse output (terminals Pout1+ and Pout1-) in type of protection intrinsic safety Ex ia IIC, for connection to a certified intrinsically safe circuit, with following entity parameters: Ui = 30 V, Ii = 100 ma, Pi = 0,75 W, Ci = 4,5 nf, Li = 0 mh. Option /EF4: Foundation Fieldbus (terminals FB+ and FB-) in type of protection intrinsic safety Ex ia, for connection to a certified intrinsically safe fieldbus in accordance with FISCO, with following maximum values: IIC: Ui = 17,5 V, Ii = 380 ma, Pi = 5,32 W, Ci = 2,7 nf, Li = 1,6 µh; IIB: Ui = 17,5 V, Ii = 460 ma, Pi = 5,32 W, Ci = 2,7 nf, Li = 1,6 µh; or for connection to a certified intrinsically safe circuit, with following entity parameters: Ui = 24 V, Ii = 250 ma, Pi = 1,2 W, Ci = 2,7 nf, Li = 1,60 µh. Page 5 of 6
Sensor outputs and inputs for connection to separate Detector Model RCCS3... (internal signals in the integral transmitter): Driving circuit (terminals D+ and D-) in type of protection intrinsic safety Ex ib IIC or Ex ib IIB (option /HP), with following entity parameters: Uo = 14,5 V, Io = 47 ma, Po = 171 mw, Lo = 15 mh, Co = 0,65 µf (IIC) or Uo = 11,7 V, Io = 124 ma, Po = 363 mw, Lo = 8 mh, Co = 10,3 µf (IIB); Sensing circuits (terminals S1+ and S1- respectively S2+ and S2-) in type of protection intrinsic safety Ex ib IIC, with following entity parameters: Uo = 14,5 V, Io = 47 ma, Po = 171 mw, Lo = 15 mh (IIC) or 60 mh (IIB), Co = 0,65 µf (IIC) or 4,07 µf (IIB); Temperature circuit (terminals TP1, TP2 and TP3) in type of protection intrinsic safety Ex ib IIC, with following entity parameters: Uo = 13,3 V, Io = 40 ma, Po = 133 mw, Lo = 20 mh (IIC) or 80 mh (IIB), Co = 0,91 µf (IIC) or 5,6 µf (IIB). The sensor output and input circuits are not infallibly galvanically isolated from the output and supply circuits The sensor input and output circuits are functionally connected to earth. Remote Detector model RCCS3...: The separate Detector is connected to the Converter with a multicore cable type RCCY03. with a maximum length of 300 m, or with an other cable that ensures infallible separation of the intrinsically safe input and output circuits, with a capacity and an inductance in accordance with the maximum allowed capacitance and inductance of the sensor circuit of the Separate Converter. The internal inductance of the Detector input and output circuits is not more than 4,2 mh per circuit. The internal capacitance is negligibly small. The drive circuit, the sense circuits and the temperature circuit are infallibly galvanically isolated from each other and from earth up to a peak voltage of 30 V. Page 6 of 6